Optimized helix angle rotors for roots-style supercharger

What is claimed is: 1. A roots blower, comprising: a housing, including; a bearing plate; an outlet portion disposed in the bearing plate and extending to an outer edge of the bearing plate; and an inlet port; a first rotor disposed in the housing; a second rotor disposed in the housing; and a pressure relief port disposed inside the housing and in fluid communication with the outlet portion; further comprising a fluid trapping area between the first and second rotors; and wherein the pressure relief port is configured to relieve fluid pressure from the fluid trapping area to the outlet portion. 2. The roots blower of claim 1 , wherein the pressure relief port is configured to provide fluid communication between the fluid trapping area and the outlet portion without providing fluid communication between the outlet portion and the inlet port. 3. The roots blower of claim 1 , wherein a volume of the trapping area decreases as the trapping area moves toward the inlet port. 4. The roots blower of claim 1 , wherein the trapping area is configured to move from a first location proximate the outlet portion to a second location proximate the inlet port. 5. The roots blower of claim 1 , wherein the trapping area is created proximate the outlet portion via a mesh of the first and second rotors. 6. The roots blower of claim 1 , wherein the bearing plate is disposed at a first axial end of the first and second rotors, wherein the inlet port is disposed at a second axial end of the first and second rotors. 7. The roots blower of claim 1 , wherein the outlet portion includes a first tapered side wall extending from the outer edge of the bearing plate and a second tapered side wall extending from the outer edge of the bearing plate. 8. The roots blower of claim 1 , and a depth of the pressure relief port is less than a depth of the outlet portion. 9. The roots blower of claim 8 , wherein the outlet portion defines a substantially trapezoidal shape. 10. The roots blower of claim 1 , wherein the pressure relief port is a first pressure relief portion; the roots blower includes a second pressure relief portion; the first pressure relief port corresponds to the first rotor; and the second pressure relief port corresponds to the second rotor. 11. The roots blower of claim 1 , wherein the pressure relief port defines a substantially triangular shape and is disposed substantially perpendicular to longitudinal axes of the first and second rotors. 12. The roots blower of claim 1 , wherein the outlet portion extends laterally outward beyond a central axis of the first rotor and laterally outward beyond a central axis of the second rotor. 13. The roots blower of claim 1 , wherein the outlet portion includes a first curved portion aligned vertically with a center of the first rotor, a second curved portion aligned vertically with a center of the second rotor, and a third curved portion disposed between and horizontally aligned with the first curved portion and the second curved portion. 14. A method of operating a roots blower, the method comprising: providing a housing defining an outlet portion and an inlet port, the housing containing a first rotor, a second rotor, and a pressure relief port in fluid communication with the outlet portion and disposed inside the housing, the pressure relief port extending from the outlet portion; rotating the first rotor and the second rotor to create a fluid trapping area between the first rotor and the second rotor; and relieving fluid pressure from the fluid trapping area to the outlet portion via the pressure relief port; wherein the housing includes a bearing plate and the outlet portion is disposed in and extends to an outer edge of the bearing plate. 15. The method of claim 14 , wherein said relieving fluid pressure from the trapping area reduces noise generated by the roots blower. 16. The method of claim 14 , wherein the trapping area overlaps with the pressure relief port in at least one position of the first and second rotors. 17. The method of claim 14 , wherein the pressure relief port is disposed in a bearing plate and the bearing plate is disposed at an axial end of the housing opposite of the inlet port. 18. The method of claim 17 , wherein the outlet portion is in fluid communication with a radial outlet port.